Adenosine triphosphatase activity and turbidity in ... - ACS Publications

KOMINZ

Studies of Adenosine Triphosphatase Activity and Turbidity in Myofibril and Actomyosin Suspensions” David R. Kominz

ABSTRACT: Steady-state adenosine triphosphatase (ATPase) determinations at low adenosine triphosphate (ATP) concentrations were performed in the pH-Stat utilizing acetyl phosphate and Escherichia co/i acetokinase as ATP-regenerating system. This permitted simultaneous measurement of ATPase activity and turbidity at 10-5-10- M ATP. It was confirmed that in addition to binding t o the hydrolytic site, ATP also binds to a clearing site in actomyosin and myofibrils. FoIlowing binding of ATP to the clearing site, removal of bound ATP or readdition of Ca2+ caused the development of heightened turbidity, suggesting that a conformational change had resulted from the ATP binding at the clearing site. The

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he existence of a second regulatory binding site for ATP on myosin, in addition t o the site of ATP hydrolysis, has been proposed by a number of workers (Nihei and Tonomura, 1959; Levy and Fleisher, 1965; Eisenberg and Moos, 1965; Kominz, 1965, 1966; Kiely and Martonosi, 1968). Levy and Fleisher (1965) stated explicitly that “the concerted action of two or more molecules of ATP (ITP) operating simultaneously or sequentially at two or more sites in the protein complex” is involved in superprecipitation. The binding of a second ATP may prevent (Kominz, 1965) or accelerate (Kominz, 1966) conformational change affecting the enzymatic site. Kiely and Martonosi (1968) propose that the triphosphate chain of a single ATP molecule may bind to either the hydrolytic or the regulatory area. It is well known that ATP and pyrophosphate can cause dissociationof actin from myosin(Weber and Portzehl, 1952)or from H-meromyosin (Perry et a / . , 1963; Yagi et a / . ,1965). ATP also causes configurational changes in the myosin or H-meromyosin which contribute to the hydrodynamic and turbidity changes (Blum and Morales, 1953). Morita (1967, 1969) has found a configurational change associated with the hydrolytic site which temporarily buriessome tyrosyland tryptophyl chromophores. At low ionic strength, the same processes are involved in the immediate clearing or turbidity development which occurs when ATP is added to an actomyosin or myofibril suspension (Maruyama and Gergely, 1962). In the presence of the native tropomyosin regulatory system (Ebashi and Ebashi, 1964; Ebashi and Endo, 1968), reducing free C a 2 + below lop6 M by means of EGTA‘ allows clearing to occur ~

~. ~~

* From

the National Institute of Arthritis and Metabolic Diseascs, National Institutes of Health, Public Health Service, U.S . Department of Health, Education, and Welfare, Bethesda, Maryland 20014. Receiced Norember 3, 1969. 1 Abbreviations used arc: EGTA, ethylene glycol bis(P-aminoethy1 ether)-A;,"-tetraacetic acid; pATP, negative logarithm of A T P conccntration; pCa, negative logarithm of Ca9- concentration.

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apparent binding constant to the clearing site and the apparent V,,,, of the actomyosin ATPase were both sensitive to traces of C a 2 + in the presence of native tropomyosin. Coupling between this binding and ATPase activation is suggested by their parallel ionic strength and temperature dependence and by the reciprocal changes in A H of binding and A H * of activation with temperature. Computations support a model based on cooperative and competitive binding. A cyclic ATPase is proposed, which couples ATPase activity to reversible actin binding through an interaction and exchange of ATP bound at the clearing site with ATP bound and split at the hydrolytic site.

at very low ATP concentrations (Kominz and Yoshioka, 1969). In our earlier work, it was not possible to examine ATPase activities at low ATP concentrations (Kominz and Yoshioka, 1969). In the present paper, a new technique of ATPase measurement has allowed simultaneous recording of turbidity changes and ATPase activity at all ATP concentrations. An indicator dye can effectively follow rapid transients (Tokiwa and Tonomura, 1965; Finlayson and Taylor, 1969), but not steady-state kinetics, at low ATP concentration. The pH-Stat has not previously been used at low ATP concentration because the usual regenerating systems, creatine kinase and pyruvate kinase, do not liberate a proton. With acetokinase as the regenerating system, it has been possible to measure simultaneously turbidity and steady-state ATPase activity at very low ATP concentration. Materials and Methods Myofibrils were prepared by homogenizing minced fresh rabbit psoas muscle for 4 min in ten volumes of 0.02 M KCI0.008 M Tris-maleate (pH 6.85) buffer containing 0.004 M EDTA. The suspension was filtered through cheesecloth and centrifuged gently at 650g for 20 min at 5 ” . The supernatant was discarded, and the precipitate was resuspended in the same solution and centrifuged twice more. A concentrated suspension of the myofibrils was slowly diluted with ice-cold glycerol to 50% and stored in the deep freeze at -20”. For measurements of ATPase and turbidity, 0.5 ml of a I-month-old 6-mg/ml suspension was added to a reaction volume of 20 ml. The reaction mixture then contained 1.25% glycerol and 5 X 10-j M EDTA. This small amount of glycerol has been found to be without significant effect upon turbidity (Maruyama and Kominz, 1969) or ATPase activity (Kominz, 1966). Calculation of Mg2f distribution took account of the EDTA present.

MYOFIBRIL ATPASE

AND TURBIDITY

Actomyosin was prepared by the method of Stowring et al. (1966). It was stored in the refrigerator at 0' until examined. Acetokinase from Escherichia coli was obtained from Boehringer Mannheim as a 5-mg/ml suspension in 2.4 M ("&S04, containing approximately 80 units of activity/mg. ATP and acetyl phosphate were reagent grade chemicals; 0.1 M stock solutions at p H 7.5 were stored frozen until use. ATPase activity and turbidity were examined simultaneously in theapparatusdescribed by Evans and Bowen (1968). Modifications allowing for temperature monitoring and control were installed during the course of this work. Because the phototube output yields per cent transmission, T, optical densities were calculated. The usage in this paper, following that of Saroff (1966) and London and Steck (1969), has been to employ association constants, denoting them by Ksubscrlpt. If the use of a dissociation constant was necessary, a small superscript d has been employed, as in pKd. Calculation of MgATP2- and free Mg2+ employed a value of 3.8 X lo4 for KU~ATP, and calculations of free Ca2+ employed a value of 8 X l o 3 for KC~ATP (Sillen and Martell, 1964). M for Although the acetokinase Kmd values of 5 X Mg2+ and acetyl phosphate (Rose, 1962) are similar to those of creatine kinase for Mgz+ and creatine phosphate (Kuby and M for Noltmann, 1962), the acetokinase Kmd of 1.5 X A D P is about ten times higher than that of creatine kinase. This implies that tenfold more A D P will be present in the steady state with acetokinase than with creatine kinase, under otherwise comparable conditions. Measurements of steadystate ATPase values were made at p H 7.5, generally in the presence of 1.5 mM acetyl phosphate, 0.05 mg of acetokinase, and 0.5 mM Mg2+; zero-order kinetics were obtained at all reaction rates studied, The reaction rate of 0.05 mg of acetokinase was 80% of the extrapolated value for infinite acetokinase concentration, when examined at pATP 4.7. This means that above pATP 4.5 the steady-state ATPase activity will be measured at ATP concentrations slightly less than the initial one, and it could be expected that artificial flattening of a plot of ATPase activity against pATP will occur as the pATP is extended beyond 5. Turbidity values were the same whether acetokinase or creatine kinase were employed as regenerating system. A small steady rate of alkali uptake occurred prior to the addition of ATP, presumably due to actomyosin-bound ADP. Tests of myofibril preparations for acetyl phosphohydrolase (Lipmann and Tuttle, 1945) were negative. In the one case where Mg*+ was allowed to become limiting (Figure 2, curve 3), this was set a t sufficiently high ATP concentration so that if the acetokinase were inhibited, a shift from net acetyl phosphate hydrolysis to ATP hydrolysis could occur. Two methods of measuring ATPase activity and turbidity were employed. In the method of gradual ATP addition, ATP was added at a very low level, and steady-state ATPase and turbidity values were measured; ATP was then added to achieve a slightly higher concentration, and the process was repeated. In this way, precise comparison of ATPase and turbidity values could be made on the same sample at 10-jM ATP. The second method is essentially that of Matsunaga and Noda (1966), as modified by Kominz and Yoshioka (1969). A myofibril o r actomyosin suspension was brought immediately to an intermediate ATP concentration, and the steady-state values of turbidity and ATPase activity

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1: Method of estimation of pATP5o above and below 18". Left: turbidity development in actomyosin suspensions; right; graphic estimation of pATP5o. The 20-ml reaction mixture contained 10 mg of actomyosin, 1.0 mM acetyl phosphate, 0.05 mg of acetokinase, and 5 X lo-' M Mg2+at pH 7.5. (A) 28", 0.15 M KCI, 1 x 10-5 M EGTA, and the following concentrations of ATP: (1) 5 x 10-5 M, (2) 4 x 10-~M, (3) 3 x M, and (4) 2 X 10-5 M. (B) 13", 0.10 M KC1 and the following concentrations of ATP: M. M, and (4) 2 X (1) 5 X M, (2) 4 X lom5 M , (3) 3.5 X FIGURE

were examined either in the absence of EGTA o r first in the presence of excess EGTA and then of added Ca2+. The midpoint of turbidity development will be called P A T P ~ ~ ( ~ Gif Tobtained A) in the presence of excess EGTA, and pATPsoccalt) if obtained in the presence of traces of free Ca*+.At temperatures above 18", steady-state turbidity values are rapidly attained, as seen in Figure l A , left; the value of pATP at 50 % turbidity development is obtained by graphic estimation (Figure l A , right). At temperatures below 18', turbidity development appears to be a n all-or-none phenomenon, so that the transition zone involves a kinetic rather than a steady-state process (Figure lB, left); for these temperatures, values of pATPso have been estimated from plots of reciprocal half-times of turbidity development (Figure lB, right). Results Myofibril ATPase Activity and Turbidity. Figure 2 plots the ATPase activity of a myofibril suspension to which increments of ATP were added under four sets of conditions. Sample 3 was Mgz+ limited; ATP was added to samples 1 and 2 in the form of MgATP2-. EGTA bound Ca2+in sample 2; an excess of Ca2+ was present in sample 4. The course of each experiment commences with the initial ATP addition in the lower right-hand corner of Figure 2 and proceeds through increasing ATP concentrations (decreasing pATP values) toward the left. There was a parallel development of ATPase activity in samples 1 and 2 until pATP 5 ; with further ATP addition, the two curves sharply diverged, This confirms the recent results of Weber (1969), in which creatine kinase was employed as regenerating system. In the presence of traces of Ca2+, the hydrolytic rate increased markedly until pATP 3.5; in the presence of EGTA, the rate started to rise but returned

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FIGURE 3 : Lineweaver-Burk plot of myofibrillar ATPase activity at 0.14 M KCI. Data from samples 1 and 2 of Figure 2 have been replotted; symbols are the same as i n Figure 2.

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2: Dependence of myofibrillar ATPase activity on substrate concentration at 0.14 M KCI. The 20-ml reaction mixture contained 3 mg of myofibrils, 1.5 mM acetyl phosphate, and 0.05 mg of acetokinase at pH 7.5 and 27-30". To each of four samples, increments of ATP or MgATP2- were added serially; the time course of each experiment proceeds from lower right to upper left. (0) Sample 1 , no EGTA. 4.5 X M Mgr+, additions of MgATP2-; ( 0 ) samM EGTA, 4.5 X ple 2, 5 X M Mgr+, additions of MgM MgZi, additions ATPZ-; (0)sample 3, no EGTA, 0.75 X of ATP; (B) after the ATP concentration in sample 3 was brought to 1.9 X M , the Mg2+concentration was raised in serial increM ; (A)sample 4,2.5 X 10-5 M Ca2+,4.5 x 1 0 - d hi ments to 3 X Mg2+,additions of ATP.

i

FIGURE

quickly to the basal level. In Figure 3, double-reciprocal plots allow tentative calculation of V,,, and p K d for the basal and activated processes. The basal ATPase appears to have a V,,,, of 0.04 pmole/mg min and pKrd of 5.5. For the activated ATPase, curve 1 suggests a V,,, of 0.18 pmoleimg min and a pKrrd of 4.25. However these values have been affected by the slight substrate inhibition of curve 1 ; the values obtainable in the presence of added Ca2- from curve 4 are a V,,, of 0.22 pmole,'mg min and a p K r I dof 4.21. Sample 3 of Figure 2 contained traces of Ca2+ and was Mg2+ limited. There was substrate inhibition at 0.1-1.9 mM ATP (pATP 4-2.7). At pATP 2.7 stepwise addition of Mg?+ gradually released the substrate inhibition and allowed the ATPase activity to approach that of the control. The concentration of MgATP2-, free MgZf and free ATP were calculated for this sample over the range of substrate inhibiM Mgz', and over the range of 0.8-25.0 X tion at 0.8 X M Mg2" at pATP 2.7. There is no correlation between ATPase activity and MgATP2-, as seen in Figure 4A. There

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4: Dependence of myofibrillar substrate ~nhibitionon (A) M g A W - , (B) free Mg2 , (C) free ATP concentrations. Data are calculated for sample 3 of Figure 2 ; symbols are the same a s in Figure 2 FIGUKL

is a correlation between ATPase activity and free MgZi-in Figure 4B ; however the hysteresis would suggest the unusual situation of a site being less available to Mg?+ binding than to release. The only correlation that is linear and reversible is between ATPase activity and free ATP in Figure 4C. T o a duplicate of sample 3, instead of multiple additions of Mg2-+,a single addition of 2.5 x lo-: M Ca2+was made at pATP 2.7. This restored the ATPase activity from 0.05 to 0.16 pmole per mg min. Since the free ATP remained virtually unchanged, this suggests that the role of free ATP in causing substrate inhibition might be related to its action on bound Ca2' (Perry and Grey, 1956; Weber, 1959). It could effect the release of this bound CaZf through a coinpetitivc binding process, through complex formation, or both. At very low ATP concentrations, all of the samples of Figure 2 developed turbidity which reached a maximum at pATP 5.0 as shown in Figure 5. Further addition of ATP lowered the turbidity again; the pATP dependencc of the turbidity reversal was steeper in the presence of EGTA than in its absence. In both cases reversal of turbidity was incomplete, and it required a much broader range of pATP than was required to define the clearing zone (Figure 5, dashed

MYOFIBRIL

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FIGURE 5 : Dependence of myofibrillar turbidity development and reversal on substrate concentration at 0.14 M KCI. (0 and 0 ) Turbidity values which accompanied the ATPase activities of samples 1 and 2, Figure 2; symbols are the same as in Figure 2. At 1.9 X M ATP, sample 1 was brought to 5 X M EGTA. ( 0 ) Four separate samples without EGTA containing 4.5 X 10P M Mgz+. Vertical bars suggest pATP of 50% turbidity development or reversal.

line). Some actomyosin samples had a similar broad range of turbidity reversal, but generally reversal could be accomplished over a range of 1 pATP unit. If the ATPase activities of Figure 2 are plotted against the turbidity values of the same samples in Figure 5, the roughly triangular relationship of Figure 6 is obtained. The base of the triangle is given by sample 2 containing EGTA, whose basal level of ATPase activity is almost independent of the state of clearing. The right side of the triangle indicates a linear relationship between ATPase activation and the development of clearing; it resembles the systems studied by Perry et a/. (1963) because presumed dissociation of actomyosin is accompanied by heightened ATPase activity. The left side of the triangle represents substrate inhibition; it is displaced to the right as in samples 2 and 3 when the free Ca2+ is reduced. Similar triangular relationships are obtained when actomyosin suspensions are examined. The addition of excess C a Z +to an EGTA sample brings it from a clear state of low ATPase activity to a position along the fully activated righthand side of the triangle, as illustrated by lines a and b. Actomyosin Turbidity and ATPase Acticity. Values of pATPjo obtained as in Figure 1A with actomyosin suspensions at 0.05, 0.10, and 0.15 ionic strength at 22-24' are listed in Table I. At each ionic strength chelation of Ca2+ with excess EGTA causes a shift of about 0.8 from P A T P ~ D ( Cto~ ~PATP~o(Ec.TA). +) For a change of 0.1 in ionic strength, there is a change of about 1.0 in the pATPjo. The turbidities observed as in Figwe 1 are never very high, and the maximum in the presence of traces of Ca2+ is not much greater than that in the presence of excess EGTA. However if increasing amounts of Ca2+are added to a sample initially containing EGTA, quite high levels of turbidity may be attained. Figure 7B portrays the experimental result of adding Ca2+ at five different ATP concentrations. In Figure 7A, the same data are replotted in terms of adding ATP to four different Ca2+ concentrations.

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ATP Requirement for Clearing in the Presence or Absence of EGTA at Various Ionic Strengthsa

TABLE I :

r/2 0.05 0.10

0.15 a

PATPSWEGTA)

3.95 4.55 5.0

pATP~o(caz+)

3.25 3.75 4.25

Estimations were performed as in Figure 1A at 22-24',

Substituting turbidity for enzymatic activity as ordinate, there is a strong resemblance between these plots and those of London and Steck's (1969) model I11 in which both activating metal and metal-substrate complex bind independently to the enzyme. The ATP activates and then inhibits as its concentration is raised. As the concentration of metal is raised, a constant level of turbidity is found at low fixed ATP, and a steep climb in turbidity is found at higher fixed ATP; not present in the model however is an upper limit of

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PATPTOTAL FIGURE 7:

P C ~ F EE R

Dependence of actomyosin turbidity development on free Ca2+and total ATP concentration. The 20-ml reaction mixture contained

10 mg of actomyosin, 1.0 mM acetyl phosphate, 0.05 mg of acetokinase, 0.10 M KCI, 1 X M EGTA, and 5 X \I Mg*+at pH 7.5 and 22-24". The experiments were performed by adding increments of 1 X 10-j \I Ca2+to suspensions held at constant ATP concentration, as shown in part B. The data are replotted as variable ATP at constant free Ca2+in part A ; the dashed lines extend the boundaries into the

region of basal turbidity at low ATP and into the region of clearing in the presence of excess Ca*+at high ATP. Arrows denote the pATI'50 at constant CarItEE in part A, and the PCaFItEE-5O at constant ATP in part B.

A T P concentration above which no addition of Ca2' can cause a turbidity increase. This limit is denoted by the dashed line a t the left of Figure 7A. The native tropomyosin system operates within the region of Figure 7A enclosed by the dashed lines. It allows clearing to occur a t low ATP concentrations with a Hill n (Loftfield

r '1

and Eigner, 1969) of 1 if the free Ca2+is low enough (here estimated as about pCa 6.3). A t higher levels of free Ca'-, it allows clearing to occur with a Hill n of 2.5-3; the same IZ is obtained for turbidity development on adding Caz' to cleared samples in Figure 7A. At high levels of free Ca?' or when native tropomyosin is absent, clearing occurs with il Hill n of 2.5-3, but no turbidity develops o n adding Ca2- to cleared samples. Two values of pATPjo obtained a t constant pCa in Figure 7A are plotted as open circles in Figure 8, and three values

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9: The relation between the initial development ol' turbidity in actomyosin suspensions upon addition of ATP, and the final increase in turbidity upon exhaustion of ATP. The 20-ml reaction mixture contained 10 mg of actomyosin in 0.10 M KCI, 5 X IO-' \ I Mg*+ at pH 7.5 and 21-22", Initial ATI' concentrations werc: ( I ) 1X M . (2) 5 X 10-5 M, (3) 4 X 10-5 M , and (4) 2 X IO.-; 21. Reversal of turbidity was obtained by adding 5 X M EGTA and then raising the ATP to 1-2.5 X lo-' M. Arrows denote additions of ATP. FIGURE

8: The dependence of 50% turbidity development on free Ca2+ and total ATP concentration at three ionic strengths. The 50% turbidity points were obtained as in Figure 7 ; closed symbols are p C a p ~ t ~ :at~ -constant ~~ ATP; open symbols are pATPooat constant Cal.ItEE. ( A , A) 0.05 M KCI, (0,0 ) 0.10 M KCI, and (C, W) 0.1 5 M KCI. FIGURE

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FIGURE10: Turbidity

development in the presence or absence of an ATP-regenerating system. Abscissa represents pATP normalized to ~ATP;O(EGTA) = 0. The 2Gml reaction mixture contained 10 M Mg2+ at pH 7.5 and 22-24". In the mg of actomyosin, 5 X presence of 1.0 mM acetyl phosphate and 0.05 mg of acetokinase, closed symbols represent the turbidity in the presence of M EGTA, open symbols represent the turbidity in the presence of 2 X M Ca2+: (A,A) 0.15 M KCI, PATPSOIEGTA) = 5.0; (.,0) 0.10 M KC1, PATPJO(EGTA) = 4.55 (see Figure 7); (0,O) 0.05 M KCI, ~ATPSOGXTA) = 3.95. In the absence of regenerating system, pATP refers to the initial ATP concentration, closed symbols represent the initial turbidity plateau, open symbols represent the final turbidity values: (V,V) 0.15 M KCI, pATPjo = 5.0; (+,O) 0.10 M KCI, pATPso = 4.55.

FIGURE 11: Comparison of pATP dependence of ATPase activity to that of turbidity. Bottom: data of Figure 10 have been plotted at original pATP values. Top: to 20-ml reaction mixture containing 8-10 mg of actomyosin, 1.0 mM acetyl phosphate, 0.05 mg of acetoM Mg2+ at pH 7.5 and kinase, 5 X M EGTA, and 5 X 21-22', gradually increasing increments of ATP were added. (. . . .) 0.15 M KCl,(--) 0.10 M KCI, and(- - - -) 0.05 M KCI.

of pCaso obtained at constant pATP in Figure 7B are plotted as closed circles in Figure 8. All five points fall on the same curve, which defines the operating zone of the native tropomyosin system at 0.1 M KCl. A similar zone has been defined for 0.15 M KCI, and a partial zone for 0.05 M KCl. Figure 8 indicates that an increase in ionic strength would have the following effect o n clearing: at fixed Ca2+, less ATP would be required to produce clearing; a t fixed ATP, more Ca would be required to maintain the bound Ca2+ at the level corresponding to 50z turbidity. Competitive K + binding would explain the increased Ca2f requirement at constant pATP; however since it also competes with H+ binding, it would produce an increased requirement for ATP at constant pCa. An electrostatic interaction, which would have the opposite effect on anions as on cations, could explain both the C a Z +and the ATP changes. If the regenerating system was omitted to allow rapid exhaustion of substrate, a plateau turbidity value persisted until the ATP was nearly gone, when a secondary rise in turbidity occurred (Figure 9). Lower plateau values resulted in higher final values of turbidity. The final turbidity could

be reversed by readdition of ATP; if EGTA was added prior to ATP, nearly complete reversibility was attainable. The cycle could be repeated several times. The results of such turbidity studies at two ionic strengths are superimposed in Figure 10. The curves for clearing in the presence of EGTA, with the PATP~~(ECT.A) values normalized at 0, are located in the lower right. Approximately one pATP unit to the left is located the curve for clearing in the presence of Ca2+. Matching each point on this clearing curve and plotted directly above it is a point representing the final turbidity value of that sample. At the right of this figure are plotted values of maximum turbidity obtained as in Figure 7B when Ca2+ is added following clearing in the presence of EGTA. In both cases clearing is required for the development of increased turbidity, and an inverse proportionality is observed between the degree of initial clearing and the degree of extra turbidity. The effects of ionic strength on the pATP dependence of turbidity development and on the pATP dependence of ATPase activity are compared in Figure 1 1 . The effect of decreasing ionic strength on turbidity is to shift the entire

pATP

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12: Temperature dependence of actomyosin turbidity and ATPase activity. The 20-rnl reaction mixture contained 10 mg of actomyosin, 1.O mM acetyl phosphate, 0.05 mg of acetokinase, and 5 X M Mg2+at pH 7.5. In the case of pATPjo values, closed symbols represent the PATPZOCEGTA) in the presence of 1 X M EGTA, open symbols represent the pATPjo(r,,i+) in the absence of EGTA: (0,O)0.15 M KCI, (I,O)0.10 M KCI, and (A)0.05 M KCI. (- -V- -) Ionic strength independent pK"1 of ATPase activity, obtained as in Figure 3. FIGURE

TABLE 11: Thermodynamic

Parameters Derived from Figure 12. -

--

-

pATPso

_ _ _ _ ~ ___._ ~

- -

(Ca 2+) (Calf) (EGTA) (EGTA) (EGTA)

0 0 0 0 0

(EGTA) (EGTA)

0.10 0.05 0,05-0.15

-

Temp ("C)

Ft2

15 10 15 10 05

>18 >18 >18 >18 >18

.

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_ _ _

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A H (kcal)

-__-30 -36 -31 -31 -32

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-5 -5 -6 -6 -5

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